GEM TPC Resolution from Charge Dispersion *

1. GEM TPC Resolution from Charge Dispersion* Madhu DixitCarleton University & TRIUMF Durham 1 - 4 September 2004 R.K.Carnegie, J.-P.Martin, H.Mes, E.Neuheimer, A.Rankin, K.Sachs & A.Tomkins Carleton University & University of Montreal * A review of material presented at Victoria Linear Collider Workshop (July 2004)

2. Introduction • Transverse diffusion sets the ultimate limit on the TPC resolution. • Wire/pad TPCs do not reach this limit due to ExB & track angle effects. • MPGD TPC has the potential to reach the diffusion limit but is limited by imprecise pad centroid determination. • Options: a) Narrower pads, increased complexity & a much larger channel count; or b) Disperse avalanche charge to improve centroid determination. 1) GEM operated with large diffusion in transfer and induction gaps - R.K.Carnegie et.al., LCWS'02, physics/0402054 (to be published in NIM). 2) Charge dispersion on a resistive anode: concept and 1st tests published: M.S.Dixit et.al., NIM A518 (2004) 721. • First results on TPC resolution with charge dispersion in a low diffusion gas (Ar/CO2:90/10, Tr= 230 m/cm) presented at LCWS 2004, Paris. ==> Resolution with charge dispersion in Ar/CO2, & in a large diffusion gas (P10,  Tr = 560 m/cm). ==> Progress in understanding the charge dispersion phenomenon. M.Dixit

3. Charge dispersion in a MPGD with a resistive anode • Modified GEM anode structurewith a high resistivity film bonded to the readout plane with an insulating layer of glue. • 2-dim RC network defined by material properties & geometry. • Point charge at r = 0 & t = 0 disperses with time. • Measure capacitively coupled charge signals on pads below. • Telegraph equation for the charge density function: (r) Q (r,t) integral over pads r / mm M.Dixit

4. Cosmic ray track resolution of a GEM TPC using the charge dispersion signal • 15 cm drift double GEM-TPC. • Ar/CO2 (90/10) & P10 gas mixtures. • 60 readout pads (2 x 6 mm2). • Anode resistivity ~ 530 k/. • C ~ 0.22 pF/mm2. • Aleph TPC preamps. Rise= 40 ns, Decay= 2 s. • 200 MHz custom 8 bit FADC readout. M.Dixit

5. A TPC track signal with charge dispersion M.Dixit

6. Tracking with the charge dispersion signal • Unusual highly variable charge pulse shape. • Pulses on charge collecting pads: Large pulses with fast fixed rise-time. The decay time depends on the system RC, the pad size & the initial charge cluster location. • Pulses on other pads: Smaller pulse heights & slow rise & decay times determined by the system RC & the pad location. • No unique recipe for the pad response function (PRF) as both the pulse height & rise-time depend on the initial charge position. • Present PRF recipe uses only the pulse height information independent of pulse rise-time. • We use part of cosmic ray data for PRF determination and for bias calibration. The remaining data is analyzed for resolution studies. M.Dixit

7. The pad response function for TPC tracks determined from the calibration data set • The PRF shape well described • by a generalized Lorentzian. • PRF(Ar/CO2 90/10) ~ 3 - 3.7 mm • depends on the drift distance. Up to 3 pads in a row contribute. P10 has large diffusion. PRF(P10) for long drift ~ 6 mm. Up to 6 pads contribute. Parameters: x, (z) PRF for 150 ns integration window centered at peak amplitude M.Dixit

8. Bias in reconstructed positions from the PRF • Local non-uniformities in theanode RC lead to ~100mm bias (systematic errors) in position determination. The bias can be removed by calibration. • The bias correction function is empirically determined from the calibration dataset. • Large transverse diffusion in P10 makes it difficult to evaluate effects of local RC non-uniformities and makes bias correction less precise. • Need a detector with more uniform RC to minimize bias. Bias for row 4 in Ar/CO2 90/10 M.Dixit

9. Transverse spatial resolution in Ar/CO2 (90/10) Charge dispersion Direct charge R.K.Carnegie et.al.,(accepted for publication in NIM). Charge dispersion improves resolutionin a low diffusion gas when there is insufficient charge sharing between pads. M.Dixit

10. Transverse spatial resolution in P10 Direct charge Charge dispersion Bias removal less effective due to large diffusion. Nevertheless, improved resolution close to the diffusion limit using charge dispersion even for P10 for which there is significant charge sharing between pads. Confirms effect first observed for ArCO2 (90/10). M.Dixit

11. The GEM charge dispersion signal Simulation versus measurement(2 mm x 6 mm pads) ~ 4.5 keV collimated x ray spot at the pad centre Detailed simulation, includes effects of intrinsic detector charge pulse shape, diffusion in the gas, and the preamp (Aleph) rise and decay time effects. Difference (induced signal not included in simulation) studied previouslyMPGD '99 (Orsay), LCWS '00 Neighboring pad dispersion signal peaks later (~150 ns)has slower decay time. Fast rising direct signal on charge collecting pad. M.Dixit

12. Scan across pads Pad 22 Pad 23 Pad 24 GEM pad response function for a charge cluster Simulation versus measurement(2 mm x 6 mm pads) Ionization from 50 m collimated x-rays. (Solid line) Simulated PRF deviates from the data due to RC nonuniformities. The deviations are consistent with observed biases. M.Dixit

13. Cosmic ray track simulation - compared to the data(67 mm drift, Ar/CO2 90/10 gas) • An exact simulation requires specifying positions & sizes of all track clusters. • Equally spaced equal size charge clusters assumed here. Single free parameter - normalization from the centre pad amplitude. M.Dixit

14. How to optimize the charge dispersion readout? • Keep the resistor noise small to maintain good S/N. (ENC ~ 200 e- for anode resistivity ~ 1000 K/ with 200 ns integration). • Efficient coupling of the readout plane with the anode. Canode-readout >> C anode-cathode will keep signal sharing with the cathode small & maximize the pad signal. (important for Micromegas). • Choose RC for to keep the intrinsic width of the PRF small for good 2-track resolution. M.Dixit

15. Diffusion effects & electronics shaping modify the charge dispersion measurement significantly Intrinsic pulse shapes (40 ns/bin) and PRF (no diffusion & no electronics shaping effects).  ~ 2.3 mm Simulated pulses & PRF with electronics & diffusion in Tesla TPC TDR gas (Ar/CH4/CO2 93/5/2) @ 4 T for 1 m drift assuming Aleph TPC preamp  ~ 3.6 mm M.Dixit

16. Pad width and RC effects on charge dispersion C = 0.22/mm2 C = 0.22/mm2 M.Dixit

17. Conclusion & future plans • Better resolution with charge dispersion than with direct charge for large & small transverse diffusion gases - P10 & Ar/CO2. • The variation with drift distance of the TPC charge dispersion resolution is near the limit from the transverse diffusion in the gas. • Nonuniform anode RC leads to ~ 100 m bias corrections. • We understand the complexities of charge dispersion. The simulation agrees well with the data. • Spatial resolution near the diffusion limit (~ 70 m for Ar with CF4) within reach for all tracks for the ILC TPC. • Future plans: • Improved anode structure with more uniform RC properties. • Charge dispersion studies with the Micromegas. • TPC magnetic field & beam tests with charge dispersion. • Preamps better matched to the charge dispersion signal. • 25 MHz digitizers to replace 200 MHz FADCs. M.Dixit

18. Effect of increasing the anode RC on pulse shapes(Vary R, keeping C constant) M.Dixit

19. Unshaped pad pulses for the wire chamber & for the charge dispersion TPC readout Wire/pad gap 1 mm 100% MPGD signal collected in ~ 100 ns The pads see close to 100% of the total avalanche charge. Full wire chamber gain is not used due to ~ 200 ns shaping. Furthermore the pads see at best ~ 40% of the anode avalanche charge. M.Dixit

20. TPC wire chamber/pad readout system The wire pulse is shaped before digitization to improve rate & 2-track TPC performance. Alice TPC shaper (base width ~ 450 ns) M.Dixit